Persistent Dopants and Phase Segregation in ... - ACS Publications

Jul 25, 2016 - Long Men,. †,§. Sarah D. Cady,. †,‡. Michael P. ... perovskites (CH3NH3PbX3−aX′a, X, X′ = I, Br, Cl) are of particular int...
2 downloads 0 Views 6MB Size
Article pubs.acs.org/cm

Persistent Dopants and Phase Segregation in Organolead MixedHalide Perovskites Bryan A. Rosales,† Long Men,†,§ Sarah D. Cady,†,‡ Michael P. Hanrahan,†,§ Aaron J. Rossini,†,§ and Javier Vela*,†,§ †

Department of Chemistry and ‡Chemical Instrumentation Facility, Iowa State University, Ames, Iowa 50011, United States US DOE Ames Laboratory, Ames, Iowa 50011, United States

§

S Supporting Information *

ABSTRACT: Organolead mixed-halide perovskites such as CH3NH3PbX3−aX′a (X, X′ = I, Br, Cl) are interesting semiconductors because of their low cost, high photovoltaic power conversion efficiencies, enhanced moisture stability, and band gap tunability. Using a combination of optical absorption spectroscopy, powder X-ray diffraction (XRD), and, for the first time, 207Pb solid state nuclear magnetic resonance (ssNMR), we probe the extent of alloying and phase segregation in these materials. Because 207Pb ssNMR chemical shifts are highly sensitive to local coordination and electronic structure, and vary linearly with halogen electronegativity and band gap, this technique can provide the true chemical speciation and composition of organolead mixed-halide perovskites. We specifically investigate samples made by three different preparative methods: solution phase synthesis, thermal annealing, and solid phase synthesis. 207Pb ssNMR reveals that nonstoichiometric dopants and semicrystalline phases are prevalent in samples made by solution phase synthesis. We show that these nanodomains are persistent after thermal annealing up to 200 °C. Further, a novel solid phase synthesis that starts from the parent, single-halide perovskites can suppress phase segregation but not the formation of dopants. Our observations are consistent with the presence of miscibility gaps and spontaneous spinodal decomposition of the mixed-halide perovskites at room temperature. This underscores how strongly different synthetic procedures impact the nanostructuring and composition of organolead halide perovskites. Better optoelectronic properties and improved device stability and performance may be achieved through careful manipulation of the different phases and nanodomains present in these materials.



INTRODUCTION Organolead halide perovskites (CH3NH3PbX3, X = I, Br, Cl) have emerged as promising semiconductors for photovoltaics due to their low cost, solution processability, and high power conversion efficiencies (>21−22%).1,2 Among their many interesting properties, organolead halide perovskites benefit from large absorption coefficients, low exciton binding energies, long exciton diffusion lengths, high dielectric constants, and intrinsic ferroelectric polarization.3−15 Organolead mixed-halide perovskites (CH3NH3PbX3−aX′a, X, X′ = I, Br, Cl) are of particular interest because they appear to further benefit from enhanced moisture stability, improved carrier relaxation time, and visible range tunability. Mixed-halide perovskites are thus useful in tandem solar cells, and because they also display intense photoluminescence, they have potential utility in lightemitting devices (LEDs).16−37 In spite of these advantages, questions surrounding the extent of alloying and phase segregation in mixed-halide perovskites remain. Films of CH3NH3PbI3−xClx cast from precursors that contain chloride exhibit improved film coverage, tunable morphologies, increased diffusion lengths, and reduced photocurrent hysteresis compared to CH3NH3PbI3 films prepared without chloride, even though no chloride is present by compositional analysis.38−44 Whether chloride is incorpo© 2016 American Chemical Society

rated into the structure is uncertain, but it has been suggested that residual chloride collects at grain boundaries.45 In the ‘CH3NH3PbI3−aBra’ series, a recent computational study proposed that bromide-rich phases such as CH3NH3PbIBr2 and CH3NH3PbI0.5Br2.5 can be thermodynamically stable against phase segregation at room temperature; however, a miscibility gap between 30 and 60% Br is only overcome above 70 °C.46 Photoinduced phase segregation of organolead mixedhalide perovskites has also been observed.47−49 Structural issues aside, phase segregation in mixed-halide perovskites is intriguing because these materials are known to easily undergo anion exchange in solution50−54 as well as between gas and solid phases.55 In fact, the fast rate of diffusion and high overall mobility of halide ions throughout the crystalline perovskite lattice55 is likely responsible for photoinduced phase separation and other unusual perovskite properties such as giant dielectric constant and photocurrent hysteresis.56,57 More research is needed to understand whether (and which) mixed-halide perovskites form stable alloys, what other phases and impurities exist as phase-segregated domains, Received: May 9, 2016 Revised: July 24, 2016 Published: July 25, 2016 6848

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials Scheme 1a

and how the various available synthetic procedures affect the true composition, speciation, and optoelectronic properties of these materials. Among the techniques best suited for the study of organolead halide perovskites is 207Pb solid state (ss) NMR.58−61 The 207Pb nucleus has a spin of 1/2, 22.6% natural abundance, and a chemical shift (δ) range spanning over 10,000 ppm.62 All of these factors make 207Pb ssNMR highly sensitive to local electronic structure, coordination environment, ligand electronegativity, and temperature. For example, the 207Pb isotropic chemical shift (δiso) of the lead dihalides (PbX2; X = I, Br, Cl) varies linearly with halide electronegativity and ionization energy (see Supporting Information (S.I.)).62−67 Because the 207Pb nucleus is highly sensitive to local electronic structure, 207Pb ssNMR can probe all crystalline, semicrystalline, and amorphous phases, and provide information about the different lead sites that may be present in mixed-halide perovskites. However, there is currently a dearth of prior 207 Pb ssNMR studies on organolead perovskites. 2H and 14N ssNMR were used to observe phase transitions and probe dynamic motions of the CH3NH3+ cations in CH3NH3PbX3.68,69 1H longitudinal relaxation times and 35Cl, 79 Br, and 127I NQR spectra were used to study the motion and phase transitions in CH3NH3PbX3.70 Very recently, 1H and 13C ssNMR spectra of a variety of lead perovskites were presented.71 Herein, we use 207Pb ssNMR to unveil the presence of both nonstoichiometric dopants and phase segregation in organolead mixed-halide perovskites. To the best of our knowledge, this is the first spectroscopic study of these materials using this technique. We find that 207Pb ssNMR is uniquely complementary to other more commonly used characterization methods such as UV−vis optical absorption and powder Xray diffraction. Using all of these techniques together, we find that dopants are persistent in perovskites even after thermal annealing to 200 °C. Moreover, these nonstoichiometric impurities form spontaneously regardless of whether the sample is made by solution phase synthesis, thermal annealing, or solid phase synthesis. In contrast, phase segregation, forming semicrystalline or amorphous products, occurs when the sample is made by solution phase synthesis, even after thermal annealing, but not by solid phase synthesis. We explain these differences in the context of recent studies on the miscibility and spinodal decomposition tendencies of organolead mixedhalide perovskites.

a

X, X′ = I, Br, Cl; 3 > a > 0.

Figure 1. Representative visual image (a) and diffuse reflectance data (b) of solid organolead halide perovskites prepared by solution phase synthesis or thermal annealing (either method gives similar results). Italicized formulas in quotation marks are calculated from synthetic loading; formulas in regular script are compositional assignments made from all experimental data. The minimum at 400 nm in (b) is an instrumental artifact.

edges of iodo-chloride perovskites such as ‘CH3NH3PbI1.5Cl1.5’ mirror that of CH3NH3PbI3 (Figure 1b). Note: Throughout this manuscript, hypothetical formulas calculated f rom the synthetic loading alone are italicized and written in quotation marks whereas actual compositional assignments determined from all of the experimental data combined are written in regular script (see below). The powder X-ray diffraction (XRD) pattern of CH3NH3PbI3 matches the tetragonal standard pattern of its most stable room temperature phase, while those of CH3NH3PbBr3 and CH3NH3PbCl3 match their cubic standard patterns (Figure 2a). Scanning electron microscopy (SEM) shows that samples are made of 0.3−2 μm particles (Figure 3). Iodo-bromide and bromo-chloride perovskites such as ‘CH3NH3PbI1.5Br1.5’ and ‘CH3NH3PbBr1.5Cl1.5’, respectively, show single sets of XRD peaks that are intermediate between those of the parent, pure halide perovskites. Scherrer analysis of the relatively broad XRD peaks of ‘CH3NH3PbI1.5Br1.5’ yields average single crystalline domain sizes of 36 ± 12 nm. In contrast, iodo-chloride perovskites such as ‘CH3NH3PbI1.5Cl1.5’ show two distinct sets of XRD peaks that clearly correspond to



RESULTS AND DISCUSSION Solution Phase Synthesis. Organolead single- and mixedhalide perovskites (CH3NH3PbX3) can be easily prepared by precipitation from solution (see Methods). In this solution phase synthesis, lead(II)- and methylammonium-halides are dissolved in N,N-dimethylformamide (DMF, X = Br, Cl) or acetonitrile (CH3CN, X = I) followed by precipitation of the desired perovskite by the addition of toluene (Scheme 1a). A progressive blue shift in the absorption edge, along with a color change from black to white, are immediately obvious as the perovskite composition changes from the less electronegative iodide to the more electronegative bromide and chloride (Figure 1a). Iodo-bromide and bromo-chloride perovskites such as ‘CH3NH3PbI1.5Br1.5’ and ‘CH3NH3PbBr1.5Cl1.5’, respectively, have absorption edges that lie in between those of the parent, single-halide perovskites. In contrast, the absorption 6849

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials

to both Hume-Rothery72 and Vegard73,74 rules, tetragonal CH3NH3PbI3 and cubic CH3NH3PbBr3 may only partially alloy because they do not share the same crystal structure even though their lattice mismatch is small (6.4%) and their halogens have similar electronegativities (χP = 3.16 for I vs 2.96 for Br) (Table 1). Cubic CH3NH3PbBr3 and cubic CH3NH3PbCl3 could form solid solutions because they adopt the same crystal structure, they have a small lattice mismatch (4.5%), and their halogens have similar electronegativities (χP = 2.96 for Br vs 2.66 for Cl) (Table 1). CH3NH3PbI3 and CH3NH3PbCl3 cannot be expected to form solid solutions to any significant extent because they form different crystal structures with a large lattice mismatch (11%) and their halogens have very different electronegativities (χP = 3.16 for I vs 2.66 for Cl) (Table 1). Unsurprisingly, annealed films of ‘CH3NH3PbI3−aCla’ do not seem to contain chloride within the detection limit of energy-dispersive X-ray spectroscopy (EDS), implying that any incorporation of chloride in the crystal lattice (x) must be extremely low.38−44 Table 1. Selected Data for CH3NH3PbX3 Perovskites

a

X

Lattice parameters (Å)

I Br Cl

75

6.3115(a), 6.3161(c) 5.9345(a)76 5.6694(a)77

Δa (%)a

χP̅ X

6.4 0 −4.5

3.16 2.96 2.66

Δa = 100 × [(ax − aBr)/aBr]. 207

Pb ssNMR of Organolead Halides. To gain more physical insight into alloying and phase segregation in organolead mixed-halide perovskites, we employed 207Pb ssNMR spectroscopy. As shown in Figure 4, the 207Pb ssNMR spectra of the single-halide perovskites show one relatively broad peak. The isotropic chemical shift (δiso) moves progressively upfield (to lower ppm value) as the halogen electronegativity and perovskite band gap increase (Figure 5). This linear correlation is similar to that observed in the lead dihalides (PbX2, X = I, Br, Cl; Figures S1 and S2).58,60,63−66 In contrast, the 207Pb ssNMR spectra of mixed-halide perovskites made by solution phase synthesis exhibit multiple peaks (Figure 4). For example, the 207Pb ssNMR spectra of mixed-halide perovskites made by solution phase synthesis with a 1:1 synthetic loading show two peaks each for ‘CH3NH3PbI1.5Br1.5’ and ‘CH3NH3PbI1.5Cl1.5’, and three peaks for ‘CH3NH3PbBr1.5Cl1.5’. In order to determine whether the presence of extra 207Pb peaks is the result of higher order NMR interactions or compositional sample variations, we collected 207Pb ssNMR spectra with and without sample spinning and at different magnetic fields. For example, the 207Pb ssNMR spectra of the ‘CH3NH3PbBr1.5Cl1.5’ sample collected with a 10 kHz magic angle spinning (MAS) frequency or with a stationary (static)

Figure 2. Powder XRD patterns (a), lattice parameter and absorption edge data (b) as a function of relative halide synthetic loading (%) for organolead halide perovskites prepared by solution phase synthesis. Italicized formulas in quotation marks are calculated from synthetic loading; formulas in regular script are compositional assignments made from all experimental data.

a physical mixture of phase-segregated CH3NH3PbI3 and CH3NH3PbCl3 (Figure 2a). As shown in Figure 2b, both the absorption edge and lattice parameter of mixed-halide perovskites show a nonlinear dependence or “bowing” on the iodide to bromide ratio, but vary linearly when transitioning from bromide to chloride. In other words, the absorption edge and lattice parameter of ‘CH3NH3PbI3−aBra’ samples made with 0−50% bromide synthetic loading (0 ≤ a ≤ 1.5) are much closer to pure bromide than to iodide. In contrast, the lattice parameter and absorption edge of ‘CH3NH3PbBr1.5Cl1.5’ lie halfway between pure bromide and chloride. The different behaviors displayed by different mixed-halide systems can be explained in part by crystallography. According

Figure 3. Representative SEM images of CH3NH3PbI3 (a), CH3NH3PbBr3 (c), and CH3NH3PbCl3 (e) made by solution phase synthesis, and of ‘CH3NH3PbI1.5Br1.5’ (b) and ‘CH3NH3PbBr1.5Cl1.5’ (d) made by solid phase synthesis (see Methods). 6850

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials

consistent with the 207Pb ssNMR spectra of other leadcontaining semiconductors.65,78,79 The full width at half-maximum (fwhm) of the 207Pb resonances is dependent on composition, going from ca. 253 ppm to 33 ppm between pure iodide and pure chloride perovskite, respectively. The 207Pb ssNMR signal broadening in these systems is likely to be primarily due to homogeneous broadening. Additional control experiments using a lower magnetic field of 9.4 T (400 MHz) (as opposed to 16.4 T (600 MHz)) lead to similar 207Pb ssNMR spectra. Superior resolution was observed at the higher field of 16.4 T (see S.I.), which indicates that the broadening of the 207Pb ssNMR peaks is primarily homogeneous. This shows that chemical shift anisotropy (CSA) is unlikely to contribute to the observed broadening to a significant extent, because broadening would then increase with applied field. Longitudinal (T1) and transverse (T2′) 207Pb relaxation time constants were also measured for the single-halides (Table S1). Static 207Pb ssNMR saturation recovery experiments yielded relatively short 207Pb T1 relaxation times between 1.1 and 1.4 s for all of the singlehalide perovskites. Application of MAS lead to a dramatic reduction in the 207Pb T1’s for both CH3NH3PbI3 (T1 ≈ 83 ms) and CH3NH3PbBr3 (T1 ≈ 104 ms), consistent with a recently proposed MAS induced halogen polarization exchange longitudinal relaxation mechanism.80 For CH3NH3PbI3 and CH3NH3PbBr3, T2’s were short (less than 90 μs) under both MAS and static sample conditions and were nearly equal to T2*, which was calculated from the full width at half-maximum of the 207Pb ssNMR peaks. Relaxation measurements directly confirm that the broadening is primarily homogeneous in nature. Both CH3NH3PbI3 and CH3NH3PbBr3 had much shorter transverse relaxation times than CH3NH3PbCl3, which suggests that dipolar/scalar coupling to the halogen nuclei could be responsible for the short transverse relaxation time constants. In summary, these observations indicate that the multiple 207Pb ssNMR peaks observed for the organolead mixed-halide perovskites arise from distinct chemical species or phases that are actually present in each sample, and that the broadening of the different 207 Pb peaks is primarily homogeneous in nature and does not arise from a distribution of isotropic chemical shifts or CSA. Correlating Structural and Spectroscopic Data. To explain our spectroscopic observations, we separately consider each of the aforementioned ‘1:1’ mixed-halide perovskites. Because δiso varies linearly with average electronegativity and band gap (Figure 5), we used these values to estimate the chemical compositions of all observed 207Pb resonances from a calibration curve determined from the single-halide perovskites (Figure 6). ‘CH3NH3PbI1.5Br1.5’ prepared by solution phase synthesis has a single set of powder XRD peaks, indicating a single crystalline phase is present (Figure 2a); however, this sample has two resolved 207Pb ssNMR peaks located at 774 and 361 ppm (Table 2 and Figure 4). The first NMR peak located at 774 ppm is in between the pure (single-halide) iodide and bromide perovskites, but closer to the latter (Figure 6a); based on its chemical shift, we attribute this resonance to the crystalline, bromide-rich perovskite CH3NH3PbIBr2 (Table 2). This assignment is consistent with both the optical and XRD data for this sample (Figures 1b and 2a). The chemical shift of the second resonance at 361 ppm is identical to that of the pure bromide perovskite (Figures 4 and 6a). However, this phase is absent from XRD and steady state optical measurements, which leads us to propose two different, alternative assignments for it:

Figure 4. Static 207Pb ssNMR spectra (22 °C) of representative organolead single- and mixed-halide perovskites prepared by solution phase synthesis, thermal annealing, and solid phase synthesis; black curves were fit to mixed Gaussian/Lorentzian peaks (see Methods). MAS lead to no substantial narrowing of the peaks (see S.I.). Italicized formulas in quotation marks are calculated from synthetic loading; formulas in regular script are compositional assignments made from all experimental data.

Figure 5. 207Pb ssNMR isotropic chemical shifts (δiso at 22 °C) observed in single- and mixed-halide-organolead perovskites prepared by solution phase synthesis as a function of average halogen electronegativity and band gap. The chemical composition of mixedhalide perovskites was estimated from a calibration curve derived from 207 Pb δiso data of single-halide perovskites.

sample spinning are virtually indistinguishable; both show three similar peaks at 160, −117, and −379 ppm (Figure S3). The presence of very broad 207Pb NMR line widths in all samples, in addition to the lack of narrowing from MAS (see S.I.), is 6851

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials

(i) One possibility is the presence of amorphous, uncrystallized CH3NH3PbBr3 (Figure 7a); (ii) Another possibility is that the

Figure 6. 207Pb ssNMR isotropic chemical shifts (δiso at 22 °C) of single- and 1:1 mixed-halide-organolead perovskites prepared by solution phase synthesis, thermal annealing, and solid phase synthesis as a function of halide composition. The chemical composition of mixed-halide perovskites was estimated from a calibration curve derived from 207Pb δiso data of single-halide perovskites.

Table 2. 207Pb ssNMR Data and Proposed Compositional Assignments for Organolead Halide Perovskites Synthetic Loadinga Solution phase synthesis ‘CH3NH3PbI3’ ‘CH3NH3PbI1.5Br1.5’ ‘CH3NH3PbBr3’ ‘CH3NH3PbBr1.5Cl1.5’

‘CH3NH3PbCl3’ ‘CH3NH3PbI1.5Cl1.5’ Thermal annealingf ‘CH3NH3PbI1.5Br1.5’ ‘CH3NH3PbBr1.5Cl1.5’

Solid phase synthesis ‘CH3NH3PbI1.5Br1.5’

‘CH3NH3PbBr1.5Cl1.5’

δiso (ppm)

Compositional Assignment(s)b

Phased (%c)

1423 774 361 361 160 −117 −379 −648 1427 −647

CH3NH3PbI3 CH3NH3PbIBr2 CH3NH3PbBr3 CH3NH3PbBr3 CH3NH3PbBr2.25Cl0.75 CH3NH3PbBr1.5Cl1.5 CH3NH3PbBr0.75Cl2.25 CH3NH3PbCl3 CH3NH3PbI3 CH3NH3PbCl3

C (100) C (26) A or/s (74)e C (100) D (21) C (56) D (23) C (100) C (n.d.) C (n.d.)

778 343 166 −109 −375

CH3NH3PbIBr2 CH3NH3PbBr3 CH3NH3PbBr2.25Cl0.75 CH3NH3PbBr1.5Cl1.5 CH3NH3PbBr0.75Cl2.25

C (53) A or/s (47)e D (24) C (55) D (21)

1126 997 872 135 −112 −358

CH3NH3PbI2.1Br0.9 CH3NH3PbI1.8Br1.2 CH3NH3PbI1.5Br1.5 CH3NH3PbBr2.25Cl0.75 CH3NH3PbBr1.5Cl1.5 CH3NH3PbBr0.75Cl2.25

D (30) C (40) D (30) D (23) C (62) D (15)

Figure 7. Cartoon illustrating possible compositional assignments for the mixed-halide perovskites ‘CH 3 NH 3 PbI 1.5 Br 1.5 ’ (a or b), ‘CH3NH3PbBr1.5Cl1.5’ (c), and ‘CH3NH3PbI1.5Cl1.5’ (d) made by solution phase synthesis and thermal annealing (see Methods). Colored octahedra represent [PbX6]4− anions while black dots represent CH3NH3+ cations. C = Crystalline, A = Amorphous, D = Dopants, c/s = core/shell. When ‘CH3NH3PbI1.5Br1.5’ is made by solid phase synthesis, the crystalline phase is closer to stoichiometric and the semicrystalline bromide-rich (amorphous or shell) phase is not observed (see Table 2).

a

Hypothetical formulas calculated from synthetic loading alone. Actual compositional assignments from all experimental data combined. cCrystalline (C), amorphous (A), core/shell (c/s), and dopant (D) phases. dNMR peak integrations (n.d. = not determined). e Not the same batch; subtle differences during solution phase synthesis result in slightly different % values. fTo 200 °C (see Methods).

whole sample consists of core/shell nanocrystals made of CH3NH3PbIBr2 cores surrounded by thin, semicrystalline CH3NH3PbBr3 shells (Figure 7b). As in other similar nanostructures, thin CH3NH3PbBr3 shells would be hard to distinguish by XRD because they would diffract weakly. In addition, in a core/shell configuration, the CH3NH3PbBr3 lattice would likely expand to better epitaxially fit onto the iodide-containing CH3NH3PbIBr2 core. However, quick and facile halide diffusion may argue against the presence of core/

b

6852

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials

2a and 4); these data are consistent with phase segregated, crystalline CH3NH3PbI3 and CH3NH3PbCl3, respectively, as expected from simple crystallographic considerations (Table 2 and Figure 7d). Thermal Annealing Experiments. A possible explanation for the presence of dopants and amorphous phases in organolead halide perovskites relates to their ability to crystallize under specific synthetic conditions. The materials initially mentioned above were synthesized at room temperature by precipitation from solution (Scheme 1a). To probe this issue, we subjected freshly made mixed-halide perovskites to thermal annealing (see Methods for details). Neither ‘CH3NH3PbI1.5Br1.5’ nor ‘CH3NH3PbBr1.5Cl1.5’ shows a significant change in color or crystal structure between 20 and 200 °C, above which both materials start showing signs of thermal decomposition (Tdec onset ≥250 °C)45,86−89 (Figures 8, S7 and S8). In the case of ‘CH3NH3PbI1.5Br1.5’, the individual powder XRD peaks become sharper upon annealing (Figure 8), indicating an increase in single crystalline domain (Scherrer) size from 36 ± 12 nm at 20 °C to 68 ± 10 nm at 200 °C. Critically, 207Pb ssNMR reveals that the composition of the different phases present in organolead mixed-halide perovskites made by solution phase synthesis remains roughly the same after thermal annealing up to 200 °C. The ‘CH3NH3PbI1.5Br1.5’ sample retains two resonances at 778 and 343 ppm (Table 2 and Figure 4), strongly indicating that both crystalline CH3NH3PbIBr2 and semicrystalline CH3NH3PbBr3, respectively, survive and are still present after annealing (Table 2 and Figure 6a). Increased iodide incorporation during the initial solution phase synthesis of the ‘CH3NH3PbI1.5Br1.5’ sample that was subjected to thermal annealing may explain the change in relative intensities between the 778 and 343 ppm peaks. This idea is supported by the variable iodide wt % values measured by ICP-MS for different supernatants. Likewise, the ‘CH3NH3PbBr1.5Cl1.5’ sample retains three resonances at 166 ppm, −109 ppm, and −375 ppm with a 1:2:1 relative integration, which is almost identical to the sample before annealing (Figure 4 and Figure 6b). These data strongly support the idea that the nonstoichiometric CH3NH3PbBr2.25Cl0.75 (166 ppm) and CH3NH3PbBr0.75Cl2.25 (−375 ppm) dopants likely form by spinodal decomposition and are persistent alongside the main stoichiometric phase CH3NH3PbBr1.5Cl1.5 (−109 ppm) after annealing. Solid Phase Synthesis. Having observed that semicrystalline, phase segregated phases and dopants can coexist and survive after thermal annealing, we questioned whether the persistence of such domains could be related to the ability of halide ions to diffuse from one solid phase to another. To probe this question, we sought to synthesize mixed-halide perovskites by a solid state synthesis that involves mixing premade, solid, single-halide perovskites and subjecting them to heat (Scheme 1b, see also Methods). As shown in Figure 9a, an equimolar (1:1) solid mixture of CH3NH3PbI3 and CH3NH3PbBr3 changes color from brownorange at 20 °C to black after heating to 200 °C. The absorption edges of the two starting materials, initially present at 20 °C, begin to move closer together and coalesce upon heating; a single absorption edge located roughly halfway between the two parent, single-halide perovskites is observed after heating to 200 °C (Figure 9b and 10a). Similarly, the two initial sets of XRD peaks corresponding to the two parent, single-halide perovskites move closer together and coalesce into a single set of XRD peaks after heating from 20 to 200 °C

shells (see below). A comparison of relative peak areas suggests that the ratio between the crystalline (C) CH3NH3PbIBr2 and semicrystalline (A or/s) CH3NH3PbBr3 phases present in this particular sample is 26% to 74% (Table 2). A possible explanation for phase segregation during the solution phase synthesis of ‘CH3NH3PbI1.5Br1.5’ is the loss of iodide precursors to the supernatant. ICP-MS and titration analyses of ‘CH3NH3PbI1.5Br1.5’ samples made by this method suggest a somewhat variable and batch dependent bromide-rich composition with an I:Br ratio between 28:72 and 19:81. ICPMS analysis of two supernatants from two separate batches suggest that iodide is present at 2.7 and 4.1 wt %, with no bromide detected in either sample. This is consistent with the presence of a recently calculated I−Br miscibility gap in this system below 70 °C.46 Interestingly, 13C cross-polarization MAS (CPMAS) ssNMR spectra of ‘CH3NH3PbI1.5Br1.5’ samples made by solution phase synthesis show two well-resolved peaks. A 13C detected proton T1 measurement showed distinct proton T1’s for each of these peaks (see S.I.). This is consistent with macroscopic segregation of the two phases, since homogeneous mixing would lead to the observation of a single common T1. ‘CH3NH3PbBr1.5Cl1.5’ made by solution phase synthesis also shows a single set of XRD peaks indicating the presence of a single, crystalline phase (Figure 2a). “Slow” XRD measurements between 29−40 degrees (2θ) showed no additional peaks (see S.I.). However, ‘CH3NH3PbBr1.5Cl1.5’ shows three 207 Pb ssNMR peaks located at 160 ppm, −117 ppm, and −379 ppm in a ca. 1:2:1 ratio (Table 2 and Figure 4). The most intense, center resonance at −117 ppm is halfway between pure bromide and chloride perovskites (Figure 6b); based on its chemical shift, and in agreement with optical and XRD data, we attribute it to crystalline CH3NH3PbBr1.5Cl1.5 (Table 2). The other two side resonances are nearly equidistant from the center resonance; based on their relative chemical shifts, they could be assigned as CH3NH3PbBr2.25Cl0.75 (160 ppm) and CH3NH3PbBr0.75Cl2.25 (−379 ppm) (Table 2 and Figure 6b). These assignments correspond to individual lead coordination environments comprised of [PbBr5Cl]4− or [PbBr4Cl2]4− octahedra and [PbBrCl 5]4− or [PbBr2Cl4]4− octahedra, respectively; because the 207Pb ssNMR peaks are broad, we are unable to distinguish between each of these pairs of individual assignments. These nonstoichiometric bromide- and chloride-rich octahedra could be present either as amorphous, uncrystallized impurities or as dopant sites within the main CH3NH3PbBr1.5Cl1.5 crystalline phase; because of their very similar peak intensities relative to each other (160 ppm, 21%; −379 ppm, 23%), yet significantly smaller than that of the main crystalline phase (−117 ppm, 56%), we suspect that they exist as dopants (Figure 7c). Such isolated Br- and Cl-rich sites would not only be difficult to resolve by XRD, but variations in the Pb-X bond lengths caused by lattice-enforced compression (for example, in [PbBr5Cl]4−) or elongation (for example, in [PbBrCl5]4−) could also shift the 207Pb resonances farther upfield and downfield, respectively, from where they could be expected based on composition alone.61,63,81 A possible explanation for these observations is the presence of spinodal decomposition of the stoichiometric Br−Cl perovskite, a wellknown phenomenon where the main crystalline phase coexists in equilibrium with a finite amount of nonstoichiometric domains.82−85 Finally, “CH3NH3PbI1.5Cl1.5“ displays two distinct, independent sets of XRD peaks along with two major 207Pb ssNMR peaks, the latter located at 1427 ppm and −647 ppm (Figures 6853

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials

Figure 8. Visual image (a), Tauc plot (b), and powder XRD patterns (c) for ‘CH3NH3PbI1.5Br1.5’ made by solution phase synthesis as well as after thermal annealing at different temperatures (see Methods). Annealing at higher temperatures (≥250 °C) resulted in partial sample decomposition (see S.I.).

Figure 9. Visual image (a), diffuse reflectance (b), and powder XRD patterns (c) for ‘CH3NH3PbI1.5Br1.5’ made by solid phase synthesis starting from an equimolar mixture of CH 3 NH 3 PbI 3 and CH3NH3PbBr3 (see Methods). Heating at higher temperatures (≥250 °C) resulted in partial sample decomposition (see S.I.).

(Figures 9c and 10a). Together, these data are consistent with the formation of ‘CH3NH3PbI1.5Br1.5’ in the solid state. A closer examination of XRD data during the solid phase synthesis of ‘CH3NH3PbI1.5Br1.5’ reveals that heating from 20 to 150 °C causes an initial decrease in the average single crystalline domain (Scherrer) sizes of the iodide-rich phase from 96 ± 19 nm to 29 ± 9 nm and of the bromide-rich phase from 110 ± 13 nm to 32 ± 10 nm (Figure 10b, solid and open circles, respectively). At this point, there is an inflection point after the two sets of peaks merge; further heating from 150 to 200 °C causes a slight increase in Scherrer size of the mixedhalide phase to 52 ± 9 nm (Figure 10b). We attribute these two distinct particle size regimes to interfacial nucleation (via halide diffusion/exchange) and growth (via coalescence) of the new

mixed-halide phase.90 A very similar behavior is observed by optical spectroscopy and powder XRD during the solid state synthesis of ‘CH3NH3PbBr1.5Cl1.5’ starting from an equimolar mixture of CH3NH3PbBr3 and CH3NH3PbCl3 solid. In this case, the inflection point between decreasing (nucleation) and increasing (growth) single average crystalline domain sizes is slightly lower than in the previous case, at ca. 100−150 °C (see S.I.). In both cases, simultaneous differential thermal− thermogravimetric analyses (DTA-TGA) showed that these solid phase reactions are accompanied by broad or “shallow” endothermic transitions with no measurable mass loss (see S.I.). A comparison of XRD and scanning electron microscopy (SEM) data showed that the mixed-halide perovskites produced in this way consist of heavily twinned particles of comparable 6854

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials

In contrast to ‘CH3NH3PbI1.5Br1.5’, the 207Pb ssNMR spectrum of ‘CH3NH3PbBr1.5Cl1.5’ prepared by solid phase synthesis still shows three 207Pb ssNMR peaks that are very similar to those observed when the sample is prepared by either solution phase synthesis or thermal annealing methods (Figure 4). Based on the specific chemical shifts, we assign these resonances as CH3NH3 PbBr2.25Cl0.75 (135 ppm, 23%), CH3NH3PbBr1.5Cl1.5 (−112 ppm, 62%), and CH3NH3PbBr0.75Cl2.25 (−358 ppm, 15%) (Table 2). Because three similar resonances are present in the 207Pb ssNMR spectra of all the ‘CH3NH3PbBr1.5Cl1.5’ samples studied, we conclude that the nonstoichiometric dopants form spontaneously as a result of spinodal decomposition (Figure 7c). These dopant sites or impurities are always naturally present and are persistent regardless of which specific synthetic method is used.



CONCLUSIONS In summary, we used a combination of optical absorption spectroscopy, powder XRD, and, for the first time, 207Pb ssNMR spectroscopy to investigate phase segregation and alloying in organolead mixed-halide perovskites. While crystallography alone accounts for phase segregation between CH3NH3PbI3 and CH3NH3PbCl3, it does not explain the true microstructure and extent of alloying between CH3NH3PbI3 and CH 3 NH 3 PbBr 3 , or between CH 3 NH 3 PbBr 3 and CH3NH3PbCl3. Compositional assignment of multiple resonances observed in the 207Pb ssNMR spectra of mixed-halide perovskites unveiled the presence of nonstoichiometric impurities or “dopants”, as well as of semicrystalline (amorphous or nanostructured core/shell) phases, which accompany the main stoichiometric crystalline phase. Critically, dopants are prevalent and persistent regardless of whether solution phase synthesis, thermal annealing, or solid phase synthesis is used to prepare these samples. In contrast, semicrystalline phases can form when samples are made by room temperature solution phase synthesis or their thermal annealing, but not by high temperature solid phase synthesis. Our thermal annealing experiments showed that the presence of dopants and semicrystalline phases is not related to the ability of organolead mixed-halide perovskites to crystallize under specific synthetic conditions. Further, solid phase synthesis experiments showed that ion diffusion is not a barrier to alloying in organolead halide perovskites. The formation of nonstoichiometric dopants is consistent with partial phase segregation caused by spinodal decomposition, which results in small composition fluctuations throughout the entire lattice that differ from the desired stoichiometric phase. In other words, these materials are composed of a main stoichiometric, alloyed phase that exists in equilibrium with two nonstoichiometric, halide-rich phases at room temperature. Combined with other more commonly used optical absorption spectroscopy and X-ray diffraction methods, 207Pb ssNMR offers unique opportunities to understand how various synthetic procedures affect the true composition, speciation, stability (against moisture, heat, light), and optoelectronic properties of these materials. Further enhancements in the efficiency and performance of perovskite-based photovoltaics and other energy conversion devices may thus be achieved through careful synthetic manipulation of such impurity phases and nanodomains.

Figure 10. Effect of annealing temperature on the lattice parameter and band gap (a) and single crystalline (Scherrer) domain size (b) measured by XRD during the solid phase synthesis of ‘CH3NH3PbI1.5Br1.5’ starting from a near equimolar mixture of CH3NH3PbI3 (solid circles) and CH3NH3PbBr3 (open circles) (see Methods).

size and morphology to those of the parent, single-halide perovskites (Figure 3). Critically, the 207Pb ssNMR spectrum of ‘CH3NH3PbI1.5Br1.5’ prepared by solid phase synthesis shows not two, but one single broad resonance at 997 ppm (Table 2 and Figure 4). Interestingly, this peak is significantly broader (fwhm = 410 ppm) than those of the parent CH 3 NH 3 PbI 3 and CH3NH3PbBr3 perovskites (fwhm = 253 and 150 ppm, respectively) (see Figure 4 and S.I.); this suggests that this peak is made of multiple overlapping resonances likely corresponding to a range of different local lead environments within a single phase. We hypothesize that these sites are nonstoichiometric I- and Br-rich dopants similar to those found in ‘CH3NH3PbBr1.5Cl1.5’ (see above). Deconvolution of the broad resonance at 997 ppm into three peaks suggests that the ‘CH3NH3PbI1.5Br1.5’ sample produced by solid phase synthesis is actually composed of CH3NH3PbI2.1Br0.9 (1126 ppm, 30%), CH3NH3PbI1.8Br1.2 (997 ppm, 40%), and CH3NH3PbI1.5Br1.5 (872 ppm, 30%) (Table 2 and Figure 4; see also S.I.). Experimental uncertainties associated with weighing equimolar amounts of starting materials may account for the CH3NH3PbI1.8Br1.2 crystalline product being slightly off the 1:1 halide ratio expected from loading alone. Thus, in contrast to solution phase synthesis, no semicrystalline CH3NH3PbBr3 is observed in ‘CH3NH3PbI1.5Br1.5’ made by solid phase synthesis. This suggests that the specific synthetic procedure has a large impact on the composition and purity of the resulting mixed iodo-bromide organolead perovskites. In contrast to solution phase synthesis, which is carried out at 20 °C, our solid phase synthesis is carried out at 200 °C, well above the maximum point of the miscibility dome proposed in the recently calculated I−Br phase diagram.46 In addition, our solid phase synthesis requires no solvent(s) so that no single precursor or major component is lost during sample isolation and purification. 6855

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials



sample would be outside of the radiofrequency coil. The 207Pb resonant frequency was 125.55 MHz, with the carrier frequency adjusted depending on the varying 207Pb chemical shifts of each sample. Pb(NO3)2 (δ = −3490 ppm, 22 °C) was used as an external calibration standard. The DEPTH pulse sequence93 (Bruker’s standard “zgbs” pulse sequence) was used to obtain both static and MAS 207Pb spectra; this pulse sequence consists of an initial 90° pulse, followed by two 180° pulses spaced by a 2 μs delay (see S.I.). This pulse sequence eliminates very broad probe background 207Pb NMR signals, which are likely due to lead in the probe’s soldering and electronics. A 90° pulse length of 3.5 μs was used, with pulse power levels calibrated on Pb(NO3)2. Spectra were acquired with a 2.1 ms acquisition time and a 10 s recycle delay after each scan. Measurements of 207Pb longitudinal relaxation times (T1) for the pure halide phases under static conditions showed that the 207Pb T1 was less than 1.4 s in all samples (see Table S1). Therefore, the recycle delay of 10 s should provide quantitative signal intensities. This is consistent with the short 207Pb T1’s reported in other lead-containing semiconductors.65,78,79 Static and 10 kHz MAS spectra were collected over a period of 1−6 days per sample. The number of scans used for each spectrum is listed in the Supporting Information, and generally varied between 1.5 and 40k. To confirm that the observed 207Pb NMR spectral broadening was primarily homogeneous, selected spectra were also acquired at a lower magnetic field of 9.4 T under both static and MAS conditions. The 9.4 T experiments were performed on a Bruker wide-bore 400 MHz solid state NMR spectrometer equipped with an AVANCE III HD console. A 4 mm HXY triple resonance probe configured in a double resonance 1 H-207Pb mode was used for experiments on the mixed-halide perovskites ‘CH3NH3PbI1.5Br1.5’ and ‘CH3NH3PbBr1.5Cl1.5’. 4.95 μs 207 Pb 90° pulse widths were used. A 1.3 mm double resonance broadband probe was used for acquisition of 207Pb ssNMR spectra of the pure halide perovskites at 9.4 T. MAS 207Pb ssNMR spectra were acquired with an MAS frequency of 50 kHz and a rotor synchronized spin echo that had a 40 μs total duration composed of two rotor periods. 1.41 μs 90° and 2.81 μs 180° pulses were used. 13C CPMAS ssNMR experiments were performed on ‘CH3NH3PbI1.5Br1.5’ (see S.I.) with a 2.5 mm triple resonance HXY probe. 13C detected proton T1 measurements were performed by applying a train of saturating π/2 pulses on 1H, followed by a variable delay, and then CP transfer to 13C for detection. All 207Pb NMR spectra were fit to simple mixed Gaussian/Lorentzian peaks using the solid line shape analysis (SOLA) module v2.2.4 included in the Bruker TopSpin v3.0 software (see S.I.).

METHODS

Materials. Lead(II) iodide (99%) and lead(II) bromide (98+%) were purchased from Acros; lead(II) chloride (99.999%) and methylamine solution (33 wt % in ethanol) from Sigma; hydroiodic acid (ACS, 55−58%), hydrobromic acid (ACS, 47.0−49.0%), hydrochloric acid (ACS, 37.2%), N,N-dimethylformamide (99.9%), and toluene (99.9%) from Fisher; acetonitrile (HPLC grade, 99.8%) from EMD Millipore. All chemicals were used as received. Synthesis. Methylammonium halides were prepared by a modified literature procedure.91 Briefly, hydroiodic acid (10 mL, 0.075 mol) or hydrobromic acid (8.6 mL, 0.075 mol) or hydrochloric acid (6.2 mL, 0.075 mol) was added to a solution of excess methylamine (24 mL, 0.192 mol) in ethanol (100 mL) at 0 °C, and the mixture stirred for 2 h. The mixture was concentrated and dried under vacuum at 60 °C for 12 h, and recrystallized from ethanol. Solution phase synthesis. CH3NH3PbI3 was synthesized by dissolving PbI2 (0.08 mmol) and CH3NH3I (0.24 mmol) in acetonitrile (20 mL), followed by precipitation via the addition of excess toluene. CH3NH3PbBr3 and CH3NH3PbCl3 were synthesized by dissolving PbBr2 (0.2 mmol) and CH3NH3Br (0.2 mmol) or PbCl2 (0.2 mmol) and CH3NH3Cl (0.2 mmol) in DMF (5 mL) followed by precipitation via the addition of excess toluene. ‘CH3NH3PbBr1.5Cl1.5’ was synthesized using the same procedure as CH3NH3PbBr3 and CH3NH3PbCl3, using 0.1 mmol of each of the four solid precursors. ‘CH3NH3PbI1.5Br1.5’ was synthesized by dissolving PbI2 (0.072 mmol), CH3NH3I (0.216 mmol), PbBr2 (0.072 mmol), and CH3NH3Br (0.216 mmol) in a mixture of acetonitrile (20 mL) and DMF (200 μL), followed by precipitation via the addition of excess toluene. ‘CH3NH3PbI1.5Cl1.5’ was synthesized by dissolving PbI2 (0.108 mmol), CH3NH3I (0.108 mmol), PbCl2 (0.108 mmol), and CH3NH3Cl (0.108 mmol) in DMF (3 mL). The mixture was concentrated and dried under vacuum, and the resulting solid could be annealed at 100 °C for 1 h. Thermal annealing. Mixed-halide perovskites prepared by solution phase synthesis were subjected to annealing between 50 and 250 °C in 50 °C increments for 1 h each. Solid phase synthesis. A stoichiometrically desired mixture of the parent, single-halide perovskites was subjected to heating between 50 and 200 °C with 50 °C increments for 1 h each. Optical Characterization. Diff use ref lectance spectra of solid films were measured with a SL1 Tungsten Halogen lamp (vis-IR), a SL3 Deuterium Lamp (UV), and a BLACK-Comet C-SR-100 spectrometer. Samples were prepared by drop-casting toluene solutions onto glass slides. Band gap values were estimated by extrapolating the linear slope of Tauc plots for direct band gap semiconductors ((absorbance × excitation energy in eV)2 over excitation energy in eV).92 Structural Characterization. Powder X-ray dif f raction (XRD) was measured using Cu Kα radiation on a Rigaku Ultima IV (40 kV, 44 mA) using a “background-less” quartz sample holder. Scherrer analysis was performed using a κ value of 0.9. Simultaneous dif ferential thermal analysis−thermogravimetric analysis (DTA-TGA) measurements were collected using a TA Instruments SDT 2960. After purging with N2 gas, 15 mg per sample was subjected to two heating−cooling cycles at 20 °C/min up to 200 °C, followed by cooling to 60 °C with a fan. Scanning electron microscopy (SEM) was performed with an FEI Quanta 250 field emission SEM at 10−11.5 kV. Samples were prepared by deposition onto an SEM slide with carbon tape, followed by coating with 5 nm of iridium. Elemental Analysis. ICP-MS data were collected on a Thermo Scientific Element 1 ICP-MS instrument Elemental Scientific, Inc. PFA-100 low-flow nebulizer. 10−15 mg of sample was dissolved in 70% nitric acid and then diluted to approximately 5 ppm with a 1% nitric acid in deionized water solution. Titration data were collected by Galbraith Laboratories, Inc. 207 Pb ssNMR. 207Pb solid state (ss) NMR spectra were measured on a Bruker widebore 14.1 T (600 MHz) NMR spectrometer equipped with an AVANCE-II console. All spectra were acquired using a 4 mm magic-angle spinning (MAS) probe in double resonance mode. Samples were packed into 4 mm Kel-F rotor inserts, which were then inserted into a 4 mm zirconia rotor. The rotor inserts were used to prevent contamination and for center packing, ensuring very little



ASSOCIATED CONTENT

S Supporting Information *

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.chemmater.6b01874. Additional methods and 207Pb ssNMR data (PDF)



AUTHOR INFORMATION

Corresponding Author

*E-mail: [email protected]. Notes

The authors declare no competing financial interest.



ACKNOWLEDGMENTS This research is supported by the U.S. Department of Energy, Office of Basic Energy Sciences, Division of Chemical Sciences, Geosciences, and Biosciences through the Ames Laboratory. The Ames Laboratory is operated for the U.S. Department of Energy by Iowa State University under Contract No. DEAC02-07CH11358. We thank K.-J. Galayda and R. S. Houk at Ames Laboratory for ICP-MS assistance. A.J.R. thanks the Ames Laboratory Royalty Account and Iowa State University for funding. 6856

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials



(20) Davies, M. L.; Carnie, M.; Holliman, P. J.; Connell, A.; Douglas, P.; Watson, T.; Charbonneau, C.; Troughton, J.; Worsley, D. Compositions, Colours and Efficiencies of Organic-Inorganic Lead Iodide/Bromide Perovskites for Solar Cells. Mater. Res. Innovations 2014, 18 (7), 482−485. (21) Kitazawa, N.; Watanabe, Y.; Nakamura, Y. Optical Properties of CH3NH3PbX3 (X = halogen) and their Mixed-Halide Crystals. J. Mater. Sci. 2002, 37, 3585−3587. (22) Zhang, M.; Yu, H.; Lyu, M.; Wang, Q.; Yun, J. H.; Wang, L. Composition-Dependent Photoluminescence Intensity and Prolonged Recombination Lifetime of Perovskite CH3NH3PbBr3‑xClx Films. Chem. Commun. 2014, 50, 11727−11730. (23) Protesescu, L.; Yakunin, S.; Bodnarchuk, M. I.; Krieg, F.; Caputo, R.; Hendon, C. H.; Yang, R. X.; Walsh, A.; Kovalenko, M. V. Nanocrystals of Cesium Lead Halide Perovskites (CsPbX3, X = Cl, Br, and I): Novel Optoelectronic Materials Showing Bright Emission with Wide Color Gamut. Nano Lett. 2015, 15, 3692−3696. (24) Sutter-Fella, C. M.; Li, Y.; Amani, M.; Ager, J. W., III; Toma, F. M.; Yablonovitch, E.; Sharp, I. D.; Javey, A. High Photoluminescence Quantum Yield in Band Gap Tunable Bromide Containing Mixed Halide Perovskites. Nano Lett. 2016, 16, 800−806. (25) Gil-Escrig, L.; Miquel-Sempere, A.; Sessolo, M.; Bolink, H. J. Mixed Iodide-Bromide Methylammonium Lead Perovskite-Based Diodes for Light Emission and Photovoltaics. J. Phys. Chem. Lett. 2015, 6, 3743−3748. (26) Zhu, W.; Bao, C.; Li, F.; Zhou, X.; Yang, J.; Yu, T.; Zou, Z. An Efficient Planar-Heterojunction Solar Cell Based on Wide-Bandgap CH3NH3PbI2.1Br0.9 Perovskite Film for Tandem Cell Applications. Chem. Commun. 2016, 52, 304−307. (27) Zhou, Y.; Yang, M.; Game, O. S.; Wu, W.; Kwun, J.; Strauss, M. A.; Yan, Y.; Huang, J.; Padture, N. P. Manipulating Crystallization of Organolead Mixed-Halide Thin Films in Antisolvent Baths for WideBandgap Perovskite Solar Cells. ACS Appl. Mater. Interfaces 2016, 8, 2232−2237. (28) Kulkarni, S. A.; Baikie, T.; Boix, P. P.; Yantara, N.; Mathews, N.; Mhaisalkar, S. Band-Gap Tuning of Lead Halide Perovskites Using a Sequentional Deposition Process. J. Mater. Chem. A 2014, 2, 9221− 9225. (29) Hoke, E. T.; Slotcavage, D. J.; Dohner, E. R.; Bowring, A. R.; Karunadasa, H. I.; McGehee, M. D. Reversible Photo-Induced Trap Formation in Mixed-Halide Perovskites for Photovoltaics. Chem. Sci. 2015, 6, 613−617. (30) Fedeli, P.; Gazza, F.; Calestani, D.; Ferro, P.; Besagni, T.; Zappettini, A.; Calestani, G.; Marchi, E.; Ceroni, P.; Mosca, R. Influence of the Synthetic Procedures on the Structural and Optical Properties of Mixed-Halide (Br, I) Perovskite Films. J. Phys. Chem. C 2015, 119, 21304−21313. (31) Sadhanala, A.; Ahmad, S.; Zhao, B.; Giesbrecht, N.; Pearce, P. M.; Deschler, F.; Hoye, R. L. Z.; Gödel, K. C.; Bein, T.; Docampo, P.; Dutton, S. E.; De Volder, M. F. L.; Friend, R. H. Blue-Green Color Tunable Solution Processable Organolead Chloride-Bromide Mixed Halide Perovskites for Optoelectronic Applications. Nano Lett. 2015, 15, 6095−6101. (32) Wei, M.; Chung, Y.-H.; Ziao, Y.; Chen, Z. Color Tunable Halide Perovskite CH3NH3PbBr3‑xClx Emission Via Annealing. Org. Electron. 2015, 26, 260−264. (33) Zhang, T.; Yang, M.; Benson, E. E.; Li, Z.; van de Lagemaat, J.; Luther, J. M.; Yan, Y.; Zhu, K.; Zhao, Y. A Facile Solvothermal Growth of Single Crystal Mixed Halide Perovskite CH3NH3Pb(Br1‑xClx)3. Chem. Commun. 2015, 51, 7820−7823. (34) Suarez, B.; Gonzalez-Pedro, V.; Ripolles, T. S.; Sanchez, R. S.; Otero, L.; Mora-Sero, I. Recombination Study of Combined Halides (Cl, Br, I) Perovskite Solar Cells. J. Phys. Chem. Lett. 2014, 5, 1628− 1635. (35) Yin, W. J.; Yan, Y.; Wei, S. H. Anomalous Alloy Properties in Mixed Halide Perovskites. J. Phys. Chem. Lett. 2014, 5, 3625−3631. (36) Kim, J.; Lee, S.-H.; Chung, C.-H.; Hong, K.-H. Systematic Analysis of the Unique Band Gap Modulation of Mixed Halide Perovskites. Phys. Chem. Chem. Phys. 2016, 18, 4423−4428.

REFERENCES

(1) Saliba, M.; Matsui, T.; Seo, J.-Y.; Domanski, K.; Correa-Baena, J.P.; Nazeeruddin, M. K.; Zakeeruddin, S. M.; Tress, W.; Abate, A.; Hagfeldt, A.; Grätzel, M. Cesium-Containing Triple Cation Perovskite Solar Cells: Improved Stability, Reproducibility and High Efficiency. Energy Environ. Sci. 2016, 9, 1989. (2) National Renewable Energy Laboratory. Best Research-Cell Efficiencies Chart. (Accessed on July 20, 2016). http://www.nrel.gov/ ncpv/images/efficiency_chart.jpg. (3) Marinova, N.; Tress, W.; Humphry-Baker, R.; Dar, M. I.; Bojinov, V.; Zakeeruddin, S. M.; Nazeeruddin, M. K.; Grätzel, M. Light Harvesting and Charge Recombination in CH3NH3PbI3 Perovskite Solar Cells Studied by Hole Transport Layer Thickness Variation. ACS Nano 2015, 9 (4), 4200−4209. (4) Kepenekian, M.; Robles, R.; Katan, C.; Sapori, D.; Pedesseau, L.; Even, J. Rashba and Dresselhaus Effects in Hybrid Organic-Inorganic Perovskites: From Basics to Devices. ACS Nano 2015, 9 (12), 11557− 11567. (5) Stranks, S. D.; Snaith, H. J. Metal-Halide Perovskites for Photovoltaic and Light-Emitting Devices. Nat. Nanotechnol. 2015, 10, 391−402. (6) Sum, T. C.; Mathews, N.; Xing, G.; Lim, S. S.; Chong, W. K.; Giovanni, D.; Dewi, H. A. Spectral Features and Charge Dynamics of Lead Halide Perovskites: Origins and Interpretations. Acc. Chem. Res. 2016, 49, 294−302. (7) Hsiao, Y.-C.; Wu, T.; Li, M.; Liu, Q.; Qin, W.; Hu, B. Fundamental Physics Behind High-Efficiency Organo-Metal Halide Perovskite Solar Cells. J. Mater. Chem. A 2015, 3, 15372−15385. (8) Sum, T. C.; Mathews, N. Advancements in Perovskite Solar Cells: Photophysics Behind the Photovoltaics. Energy Environ. Sci. 2014, 7, 2518−2534. (9) Yin, W.-J.; Yang, J.-H.; Kang, J.; Yan, Y.; Wei, S.-H. Halide Perovskite Materials for Solar Cells: A Theoretical Review. J. Mater. Chem. A 2015, 3, 8926−8942. (10) Green, M. A.; Ho-Baillie, A.; Snaith, H. J. The Emergence of Perovskite Solar Cells. Nat. Photonics 2014, 8, 506−514. (11) Gao, P.; Grätzel, M.; Nazeeruddin, M. Organohalide Lead Perovskites for Photovoltaic Applications. Energy Environ. Sci. 2014, 7, 2448−2463. (12) Kazim, S.; Nazeeruddin, S. K.; Grätzel, M.; Ahmad, S. Perovskite as Light Harvester: A Game Changer in Photovoltaics. Angew. Chem., Int. Ed. 2014, 53, 2812−2824. (13) Park, N. G. Organometal Perovskite Light Absorbers Toward a 20% Efficiency Low-Cost Solid-State Mesoscopic Solar Cell. J. Phys. Chem. Lett. 2013, 4, 2423−2429. (14) Song, T. B.; Chen, Q.; Zhou, H.; Jiang, C.; Wang, H. H.; Yang, Y.; Liu, Y.; You, J.; Yang, Y. Perovskite Solar Cells: Film Formation and Properties. J. Mater. Chem. A 2015, 3, 9032−9050. (15) Snaith, H. J. Perovskites: The Emergence of a New Era for LowCost, High-Efficiency Solar Cells. J. Phys. Chem. Lett. 2013, 4, 3623− 3630. (16) Zhu, F.; Men, L.; Guo, Y.; Zhu, Q.; Bhattacharjee, U.; Goodwin, P. M.; Petrich, J. W.; Smith, E. A.; Vela, J. Shape Evolution and Single Particle Luminescence of Organometal Halide Perovskite Nanocrystals. ACS Nano 2015, 9, 2948−2959. (17) Bade, S. G. R.; Li, J.; Ling, Y.; Tian, Y.; Dilbeck, T.; Besara, T.; Geske, T.; Gao, H.; Ma, B.; Hanson, K.; Siegrist, T.; Xu, C.; Yu, Z. Fully Printed Halide Perovskite Light-Emitting Diodes with Silver Nanowire Electrodes. ACS Nano 2016, 10, 1795−1801. (18) Noh, J. H.; Im, S. H.; Heo, J. H.; Mandal, T. N.; Seok, S. I. Chemical Management for Colorful, Efficient, and Stable InorganicOrganic Hybrid Nanostructured Solar Cells. Nano Lett. 2013, 13, 1764−1769. (19) Sadhanala, A.; Deschler, F.; Thomas, T. H.; Dutton, S. E.; Goedel, K. C.; Hanusch, F. C.; Lai, M. L.; Steiner, U.; Bein, T.; Docampo, P.; Cahen, D.; Friend, R. H. Preparation of Single-Phase Films of CH3NH3Pb(I1‑xBrx)3 with Sharp Optical Band Edges. J. Phys. Chem. Lett. 2014, 5, 2501−2505. 6857

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials (37) Madjet, M. E.-A.; Akimov, A. V.; El-Mellouhi, F.; Berdiyorov, G. R.; Ashhab, S.; Tabet, N.; Kais, S. Enhancing the Carrier Thermalization Time in Organometallic Perovskites by Halide Mixing. Phys. Chem. Chem. Phys. 2016, 18, 5219−5231. (38) Chae, J.; Dong, Q.; Huang, J.; Centrone, A. Chloride Incorporation Process in CH3NH3PbI3‑xClx Perovskites Via Nanoscale Bandgap Maps. Nano Lett. 2015, 15, 8114−8121. (39) Xie, F. X.; Zhang, D.; Su, H.; Ren, X.; Wong, K. S.; Grätzel, M.; Choy, W. C. H. Vacuum-Assisted Thermal Annealing of CH3NH3PbI3 for Highly Stable and Efficient Perovskite Solar Cells. ACS Nano 2015, 9 (1), 639−646. (40) Williams, S. T.; Zuo, F.; Chueh, C. C.; Liao, C. Y.; Liang, P. W.; Jen, A. K. Y. Role of Chloride in the Morphological Evolution of Organo-Lead Halide Perovskite Thin Films. ACS Nano 2014, 8 (10), 10640−10654. (41) Tidhar, Y.; Edri, E.; Weissman, H.; Zohar, D.; Hodes, G.; Cahen, D.; Rybtchinski, B.; Kirmayer, S. Crystallization of Methyl Ammonium Lead Halide Perovskites: Implications for Photovoltaic Applications. J. Am. Chem. Soc. 2014, 136, 13249−13256. (42) Edri, E.; Kirmayer, S.; Mukhopadhyay, S.; Gartsman, K.; Hodes, G.; Cahen, D. Elucidating the Charge Carrier Separation and Working Mechanism of CH3NH3PbI3‑xClx Perovskite Solar Cells. Nat. Commun. 2014, 5, 1−8. (43) Zhao, Y.; Zhu, K. CH3NH3Cl-Assisted One-Step Solution Growth of CH3NH3PbI3: Stucture, Charge-Carrier Dynamics, and Photovoltaic Properties of Perovskite Solar Cells. J. Phys. Chem. C 2014, 118, 9412−9418. (44) Colella, S.; Mosconi, E.; Fedeli, P.; Listorti, A.; Gazza, F.; Orlandi, F.; Ferro, P.; Besagni, T.; Rizzo, A.; Calestani, G.; Gigli, G.; De Angelis, F.; Mosca, R. MAPbI3‑xClx Mixed Halide Perovskite for Hybrid Solar Cells: The Role of Chloride as Dopant on the Transport and Structural Properties. Chem. Mater. 2013, 25, 4613−4618. (45) Yang, B.; Keum, J.; Ovchinnikova, O. S.; Belianinov, A.; Chen, S.; Du, M.-H.; Ivanov, I. N.; Rouleau, C. M.; Geohegan, D. B.; Xiao, K. Deciphering Halogen Competition in Organometallic Halide Perovskite Growth. J. Am. Chem. Soc. 2016, 138, 5028−5035. (46) Brivio, F.; Caetano, C.; Walsh, A. Thermodynamic Origin of Photoinstability in the CH3NH3Pb(I1‑xBrx)3 Hybrid Halide Perovskite Alloy. J. Phys. Chem. Lett. 2016, 7, 1083−1087. (47) Hoke, E. T.; Slotcavage, D. J.; Dohner, E. R.; Bowring, A. R.; Karunadasa, H. I.; McGehee, M. D. Reversible Photo-Induced Trap Formation in Mixed-Halide Perovskites for Photovoltaics. Chem. Sci. 2015, 6, 613−617. (48) Niemann, R. G.; Kontos, A. G.; Palles, D.; Kamitsos, E. I.; Kaltzoglou, A.; Brivio, F.; Falaras, P.; Cameron, P. J. Halogen Effects on Ordering and Bonding of CH3NH3+ in CH3NH3PbX3 (X = Cl, Br, I) Hybrid Perovskites: A Vibrational Spectroscopic Study. J. Phys. Chem. C 2016, 120, 2509−2519. (49) Guerrero, A.; You, J.; Aranda, C.; Kang, Y. S.; Garcia-Belmonte, G.; Zhou, H.; Bisquert, J.; Yang, Y. Interfacial Degradation of Planar Lead Halide Perovskite Solar Cells. ACS Nano 2016, 10, 218−224. (50) Jang, D. M.; Park, K.; Kim, D. H.; Park, J.; Shojaei, F.; Kang, H. S.; Ahn, J.-P.; Lee, J. W.; Song, J. K. Reversible Halide Exchange Reaction of Organometal Trihalide Perovskite Colloidal Nanocrystals for Full-Range Band Gap Tuning. Nano Lett. 2015, 15, 5191−5199. (51) Pellet, N.; Teuscher, J.; Maier, J.; Grätzel, M. Transforming Hybrid Organic Inorganic Perovskites by Rapid Halide Exchange. Chem. Mater. 2015, 27, 2181−2188. (52) Wong, A. B.; Lai, M.; Eaton, S. W.; Yu, Y.; Lin, E.; Dou, L.; Fu, A.; Yang, P. Growth and Anion Exchange Conversion of CH3NH3PbX3 Nanorod Arrays for Light-Emitting Diodes. Nano Lett. 2015, 15, 5519−5524. (53) Akkerman, Q. A.; D’Innocenzo, V.; Accornero, S.; Scarpellini, A.; Petrozza, A.; Prato, M.; Manna, L. Tuning the Optical Properties of Cesium Lead Halide Perovskite Nanocrystals by Anion Exchange Reactions. J. Am. Chem. Soc. 2015, 137, 10276−10281. (54) Zhu, W.; Bao, C.; Li, F.; Yu, T.; Gao, H.; Yi, Y.; Yang, J.; Fu, G.; Zhou, X.; Zou, Z. A Halide Exchange Engineering for

CH3NH3PbI3‑xBrx Perovskite Solar Cells with High Performance and Stability. Nano Energy 2016, 19, 17−26. (55) Li, G.; Ho, J. Y.-L.; Wong, M.; Kwok, H. S. Reversible Anion Exchange Reaction in Solid Halide Perovskites and Its Implication in Photovoltaics. J. Phys. Chem. C 2015, 119, 26883−26888. (56) Yuan, Y.; Huang, J. Ion Migration in Organometal Trihalide Perovskite and Its Impact on Photovoltaic Efficiency and Stability. Acc. Chem. Res. 2016, 49, 286−293. (57) Eames, C.; Frost, J. M.; Barnes, P. R. F.; O’Regan, B. C.; Walsh, A.; Islam, M. S. Ionic Transport in Hybrid Lead Iodide Perovskite Solar Cells. Nat. Commun. 2015, 6, 7497. (58) Dybowski, C.; Neue, G. Solid State 207Pb NMR Spectroscopy. Prog. Nucl. Magn. Reson. Spectrosc. 2002, 41, 153−170. (59) Wrackmeyer, B. Application of 207Pb NMR Parameters. Annu. Rep. NMR Spectrosc. 2002, 47, 1−37. (60) Dmitrenko, O.; Bai, S.; Beckmann, P. A.; Van Bramer, S.; Vega, A.; Dybowski, C. The Relationship between 207Pb NMR Chemical Shift and Solid-State Structure in Pb(II) Compounds. J. Phys. Chem. A 2008, 112, 3046−3052. (61) Fayon, F.; Farnan, I.; Bessada, C.; Coutures, J.; Massiot, D.; Coutures, J. P. Empirical Correlations Between 207Pb NMR Chemical Shifts and Structure in Solids. J. Am. Chem. Soc. 1997, 119, 6837− 6843. (62) Dmitrenko, O.; Bai, S.; Dybowski, C. Prediction of 207Pb NMR Parameters for the Solid Ionic Lead(II) Halides Using the Relativistic ZORA-DFT Formalism: Comparison with the Lead-Containing Molecular Systems. Solid State Nucl. Magn. Reson. 2008, 34, 186−190. (63) Dybowski, C.; Smith, M. L.; Hepp, M. A.; Gaffney, E. J.; Neue, G.; Perry, D. L. 207Pb NMR Chemical-Shift Tensors of the Lead (II) Halides and the Lead (II) Hydroxyhalides. Appl. Spectrosc. 1998, 52, 426−429. (64) Nizam, M.; Suits, B. H.; White, D. NMR Chemical Shifts and the Electronic Structure of Lead in Lead Halides. J. Magn. Reson. 1989, 82, 441−453. (65) Taylor, R. E.; Beckmann, P. A.; Bai, S.; Dybowski, C. 127I and 207 Pb Solid-State NMR Spectroscopy and Nuclear Spin Relaxation in PbI2: A Preliminary Study. J. Phys. Chem. C 2014, 118, 9143−9153. (66) Glatfelter, A.; Stephenson, N.; Bai, S.; Dybowski, C.; Perry, D. L. Quantitative Determination of Lead in Mixtures of Lead(II) Halides Using Solid-State 207Pb NMR Spectroscopy. Analyst 2006, 131, 1207− 1209. (67) Glatfelter, A.; Dybowski, C.; Kragten, D. D.; Bai, S.; Perry, D. L.; Lockard, J. Solid-State 207Pb NMR Studies of Mixed Lead Halides, PbFX (X = Cl, Br, or I). Spectrochim. Acta, Part A 2007, 66, 1361− 1363. (68) Wasylishen, R. E.; Knop, O.; Macdonald, J. B. Cation Rotation in Methylammonium Lead Halides. Solid State Commun. 1985, 56, 581−582. (69) Knop, O.; Wasylishen, R. E.; White, M. A.; Cameron, T. S.; Vanoort, M. J. M. Alkylammonium Lead Halides 0.2. CH3NH3PbCl3, CH3NH3PbBr3, CH3NH3PbI3 Perovskites − Cuboctahedral Halide Cages with Isotropic Cation Reorientation. Can. J. Chem. 1990, 68, 412−422. (70) Xu, Q.; Eguchi, T.; Nakayama, H.; Nakamura, N.; Kishita, M. Molecular Motions and Phase-Transitions in Solid CH3NH3PbCl3, CH3NH3PbBr3, CH3NH3PbI3, as Studied by NMR and NQR. Z. Naturforsch. A − J. Phys. Sci. 1991, 46, 240−246. (71) Baikie, T.; Barrow, N. S.; Fang, Y.; Keenan, P. J.; Slater, P. R.; Piltz, R. O.; Gutmann, M.; Mhaisalkar, S. G.; White, T. J. A Combined Single Crystal Neutron/X-Ray Diffraction and Solid-State Nuclear Magnetic Resonance Study of the Hybrid Perovskites CH3NH3PbX3 (X = I, Br and Cl). J. Mater. Chem. A 2015, 3, 9298−9307. (72) Hume-Rothery, W. Researches on the Nature, Properties, and Conditions of Formation of Intermetallic Compounds, with Special Reference to Certain Compounds of Tin.-I.-V. J. Inst. Met. 1926, 35, 295−348. (73) Vegard, L. Die Konstitution der Mischkristalle und die Raumfüllung der Atome. Eur. Phys. J. A 1921, 5, 17−26. 6858

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859

Article

Chemistry of Materials (74) Denton, A. R.; Ashcroft, N. W. Vegard’s Law. Phys. Rev. A: At., Mol., Opt. Phys. 1991, 43 (6), 3161−3164. (75) Stoumpos, C. C.; Malliakas, C. D.; Kanatzidis, M. G. Semiconducting Tin and Lead Iodide Perovskites with Organic Cations: Phase Transitions, High Mobilities, and Near-Infrared Photoluminescent Properties. Inorg. Chem. 2013, 52, 9019−9038. (76) Su, J.; Chen, D. P.; Lin, C. T. Growth of Large CH3NH3PbX3 (X = I, Br) Single Crystals in Solution. J. Cryst. Growth 2015, 422, 75− 79. (77) Chi, L.; Swainson, I.; Cranswick, L.; Her, J.-H.; Stephens, P.; Knop, O. The Ordered Phase of Methylammonium Lead Chloride CH3ND3PbCl3. J. Solid State Chem. 2005, 178, 1376−1385. (78) Taylor, R. E.; Alkan, F.; Koumoulis, D.; Lake, M. P.; King, D.; Dybowski, C.; Bouchard, L.-S. A Combined NMR and DFT Study of Narrow Gap Semiconductors: The Case of PbTe. J. Phys. Chem. C 2013, 117 (17), 8959−8967. (79) Koumoulis, D.; Taylor, R. E.; King, D., Jr.; Bouchard, L.-S. NMR Study of Native Defects in PbSe. Phys. Rev. B: Condens. Matter Mater. Phys. 2014, 90, 1−6. (80) Shmyreva, A. A.; Safdari, M.; Furó, I.; Dvinskikh, S. V. NMR longitudinal Relaxation Enhancement in Metal Halides by Heteronuclear Polarization Exchange During Magic-Angle Spinning. J. Chem. Phys. 2016, 144, 224201. (81) Smith, J. V.; Blackwell, S. Nuclear Magnetic Resonance of Silica Polymorphs. Nature 1983, 303, 223−225. (82) Findik, F. Improvements in Spinodal Alloys from Past to Present. Mater. Eng. 2012, 42, 131−146. (83) Binder, K.; Billotet, C.; Mirold, P. On the Theory of Spinodal Decomposition in Solid and Liquid Binary Mixtures. Z. Phys. B: Condens. Matter Quanta 1978, 30, 183−195. (84) Binder, K. Spinodal Decomposition in Confined Geometry. J. Non-Equilib. Thermodyn. 1998, 23, 1−44. (85) Androulakis, J.; Lin, C.-H.; Kong, H.-J.; Uher, C.; Wu, C.-I.; Hogan, T.; Cook, B. A.; Caillat, T.; Paraskevopoulos, K. M.; Kanatzidis, M. G. Spinodal Decomposition and Nucleation and Growth as a Means to Bulk Nanostructured Thermoelectrics: Enhanced Performance in Pb1‑xSnxTe-PbS. J. Am. Chem. Soc. 2007, 129, 9780−9788. (86) Dualeh, A.; Gao, P.; Seok, S. I.; Nazeeruddin, M. K.; Grätzel, M. Thermal Behavior of Methylammonium Lead-Trihalide Perovskite Photovoltaic Light Harvesters. Chem. Mater. 2014, 26, 6160−6164. (87) Borchert, J.; Boht, H.; Fränzel, W.; Csuk, R.; Scheer, R. Structural Investigation of Co-Evaporated Methylammonium Lead Halide Perovskite Films During Growth and Thermal Decomposition Using Different PbX2 (X = I, Cl) Precursors. J. Mater. Chem. A 2015, 3, 19842−19849. (88) Williams, A. E.; Holliman, P. J.; Carnie, M. J.; Davies, M. L.; Worsley, D. A.; Watson, R. M. Perovskite Processing for Photovoltaics: A Spectrothermal Evaluation. J. Mater. Chem. A 2014, 2, 19338−19346. (89) Tang, L.-D.; Mei, H.; Wang, B.; Peng, S. Study on Structure, Thermal Stabilization and Light Absorption of Lead-Bromide Perovskite Light Harvesters. J. Mater. Sci.: Mater. Electron. 2015, 26, 8726−8731. (90) Reichert, M. D.; Lin, C.-C.; Vela, J. How Robust Are Semiconductor Nanorods? Investigating the Stability and Chemical Decomposition Pathways of Photoactive Nanocrystals. Chem. Mater. 2014, 26, 3900−3908. (91) Lee, M. M.; Teuscher, J.; Miyasaka, T.; Murakami, T. N.; Snaith, H. J. Efficient Hybrid Solar Cells Based on Meso-Superstructured Organometal Halide Perovskites. Science 2012, 338, 643−647. (92) Tauc, J.; Grigorovici, R.; Vancu, A. Optical Properties and Electronic Structure of Amorphous Germanium. Phys. Status Solidi B 1966, 15, 627−637. (93) Cory, D. G.; Ritchey, W. M. Suppression of Signals from the Probe in Bloch Decay Spectra. J. Magn. Reson. 1988, 80 (1), 128−132.

6859

DOI: 10.1021/acs.chemmater.6b01874 Chem. Mater. 2016, 28, 6848−6859